Centripetal Force

A the centripetal force which is equal to the Tension on the Holon string, which is pulling against the spring force which is our centripetal force when our radius is constant. The normal force is always pulling up, and the force of gravity always pulling down, they are cancel each other out in this situation.So even though we are adding more mass it does not have any effect on the centripetal force. Equation relating the net force (FCC) to the speed (v) of an object moving in uniform circular motion. F c = This equation shows that the net force required for an object to move in a circle is directly proportional to the square of the speed of the object. For a constant mass ND radius, the FCC is proportional to the speeds. VA 2 The factor by which the net force is altered is the square of the factor by which the speed is altered.Subsequently, if the speed of the object is doubled, the net force required for that object's circular motion is quadrupled. And if the speed of the object is halved (decreased by a factor of 2), the net force required is decreased by a factor of 4. We find the result of our experiment dose agrees with above. In our experiment we keep radius constant so our force stays the same, and as we increased mass on each trail we see our velocity keeps decreasing gradually. Centripetal Force A the centripetal force which is equal to the Tension on the Holon string, which is pulling against the spring force which is our centripetal force when our radius is constant. The normal force is always pulling up, and the force of gravity always pulling down, they are cancel each other out in this situation.So even though we are adding more mass it does not have any effect on the centripetal force. Equation relating the net force (FCC) to the speed (v) of an object moving in uniform circular motion. F c = This equation shows that the net force required for an object to move in a circle is directly proportional to the square of the speed of the object. For a constant mass ND radius, the FCC is proportional to the speeds. VA 2 The factor by which the net force is altered is the square of the factor by which the speed is altered.Subsequently, if the speed of the object is doubled, the net force required for that object's circular motion is quadrupled. And if the speed of the object is halved (decreased by a factor of 2), the net force required is decreased by a factor of 4. We find the result of our experiment dose agrees with above. In our experiment we keep radius constant so our force stays the same, and as we increased mass on each trail we see our velocity keeps decreasing gradually.